Physical Chemistry Third Edition

(C. Jardin) #1

27.4 Classical Statistical Mechanics 1135


The integral over the momentum components factors into a product of integrals, one
for each momentum component, such as
∫∞

−∞

exp

(

−p^2 x 1
2 mkBT

)

dpx 1 (2πmkBT)^1 /^2 (27.4-5)

where we have looked up the integral in Appendix C. Every momentum component
gives the same result after integration, so that

Zcl(2πmkBT)^3 N/^2


e−V(q)/kBTdq(2πmkBT)^3 N/^2 ζ (27.4-6)

The integralζis called theconfiguration integral

ζ


e−V(q)/kBTdq (27.4-7)

This is a 3N-fold integral over all of the coordinates.

Exercise 27.3
Carry out the derivation of the classical canonical probability density by considering a system
made up of two subsystems.

Dilute Gases in the Classical Canonical Ensemble


The equations we have written apply to any system of atoms without electronic exci-
tation, whether the system is a solid, liquid, or gas. If the system consists of a single
particle in a rectangular box with its lower left rear corner at the origin and with dimen-
sionsa,b, andcin thex,y, andzdirections, the configuration integral would be

ζ

∫c

0

∫b

0

∫a

0

e−V(x,y,z)/kBTdxdydz

(

system of a single particle
in a rectangular box

)

(27.4-8)

If there are no forces on the particle inside the box, its potential energy is equal to a
constant, which we can set equal to zero:

ζ

∫c

0

∫b

0

∫a

0

e^0 dxdydzabcV



single particle
in a box with
zero potential energy


⎠ (27.4-9)

If the system is a dilute gas ofNatoms we can ignore the intermolecular interactions
and each particle moves as though alone in the box. If we set the constant potential
energy equal to zero the configuration integral is a product ofNintegrals like that of
Eq. (27.4-9):

ζ


e^0 d^3 r 1 d^3 r 2 ...d^3 rNVN

(

dilute monatomic gas
with zero potential energy

)

(27.4-10)

The classical canonical partition function is

Zcl(2πmkBT)^3 N/^2 VNzNcl

(

dilute monatomic gas
with zero potential energy

)

(27.4-11)
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